Related question: Time Complexity of InOrder Tree Traversal of Binary Tree O(N)?, however it is based on a traversal via recursion (so in O(log N) space) while iterators allow a consumption of only O(1) space.

In C++, there normally is a requirement that incrementing an iterator of a standard container be a O(1) operation. With most containers it's trivially proved, however with `map`

and such, it seems a little more difficult.

- If a
`map`

were implemented as a skip-list, then the result would be obvious - However they are often implemented as red-black trees (or at least as binary search trees)

So, during an in-order traversal there are moments where the "next" value is not so easily reached. For example should you be pointing at the bottom-right leaf of the left subtree, then the next node to traverse is the root, which is `depth`

steps away.

I have tried "proving" that the algorithmic complexity (in terms of "steps") was *amortized* O(1), which seems alright. However I don't have the demonstration down yet.

Here is a small diagram I traced for a tree with a depth of 4, the numbers (in the place of the nodes) represent the number of steps to go from that node to the next one during an in-order traversal:

```
3
2 2
1 1 1 1
1 2 1 3 1 2 1 4
```

*Note: the right-most leaf has a cost of 4 in case this would be a sub-tree of a larger tree.*

The sum is 28, for a total number of nodes of 15: thus a cost less than 2 per node, in average, which (if it holds up) would be a nice amortized cost. So:

- During in-order traversal, is incrementing the iterator really O(1) for a balanced (and full) binary search tree ?
- May the result be extended to cover non-full binary search trees ?

`O(1)`

memory overall or amortized time to increment the iterator? in-order traversal cannot be`O(1)`

time overall. – IVlad Oct 14 '12 at 13:04